# frozen_string_literal: true

# :markup: markdown
#   irb.rb - irb main module
#       by Keiju ISHITSUKA(keiju@ruby-lang.org)
#

require "ripper"
require "reline"

require_relative "irb/init"
require_relative "irb/context"
require_relative "irb/default_commands"

require_relative "irb/ruby-lex"
require_relative "irb/statement"
require_relative "irb/input-method"
require_relative "irb/locale"
require_relative "irb/color"

require_relative "irb/version"
require_relative "irb/easter-egg"
require_relative "irb/debug"
require_relative "irb/pager"

# ## IRB
#
# Module IRB ("Interactive Ruby") provides a shell-like interface that supports
# user interaction with the Ruby interpreter.
#
# It operates as a *read-eval-print loop*
# ([REPL](https://en.wikipedia.org/wiki/Read%E2%80%93eval%E2%80%93print_loop))
# that:
#
# *   ***Reads*** each character as you type. You can modify the IRB context to
#     change the way input works. See [Input](rdoc-ref:IRB@Input).
# *   ***Evaluates*** the code each time it has read a syntactically complete
#     passage.
# *   ***Prints*** after evaluating. You can modify the IRB context to change
#     the way output works. See [Output](rdoc-ref:IRB@Output).
#
#
# Example:
#
#     $ irb
#     irb(main):001> File.basename(Dir.pwd)
#     => "irb"
#     irb(main):002> Dir.entries('.').size
#     => 25
#     irb(main):003* Dir.entries('.').select do |entry|
#     irb(main):004*   entry.start_with?('R')
#     irb(main):005> end
#     => ["README.md", "Rakefile"]
#
# The typed input may also include [\IRB-specific
# commands](rdoc-ref:IRB@IRB-Specific+Commands).
#
# As seen above, you can start IRB by using the shell command `irb`.
#
# You can stop an IRB session by typing command `exit`:
#
#     irb(main):006> exit
#     $
#
# At that point, IRB calls any hooks found in array `IRB.conf[:AT_EXIT]`, then
# exits.
#
# ## Startup
#
# At startup, IRB:
#
# 1.  Interprets (as Ruby code) the content of the [configuration
#     file](rdoc-ref:IRB@Configuration+File) (if given).
# 2.  Constructs the initial session context from [hash
#     IRB.conf](rdoc-ref:IRB@Hash+IRB.conf) and from default values; the hash
#     content may have been affected by [command-line
#     options](rdoc-ref:IB@Command-Line+Options), and by direct assignments in
#     the configuration file.
# 3.  Assigns the context to variable `conf`.
# 4.  Assigns command-line arguments to variable `ARGV`.
# 5.  Prints the [prompt](rdoc-ref:IRB@Prompt+and+Return+Formats).
# 6.  Puts the content of the [initialization
#     script](rdoc-ref:IRB@Initialization+Script) onto the IRB shell, just as if
#     it were user-typed commands.
#
#
# ### The Command Line
#
# On the command line, all options precede all arguments; the first item that is
# not recognized as an option is treated as an argument, as are all items that
# follow.
#
# #### Command-Line Options
#
# Many command-line options affect entries in hash `IRB.conf`, which in turn
# affect the initial configuration of the IRB session.
#
# Details of the options are described in the relevant subsections below.
#
# A cursory list of the IRB command-line options may be seen in the [help
# message](https://raw.githubusercontent.com/ruby/irb/master/lib/irb/lc/help-message),
# which is also displayed if you use command-line option `--help`.
#
# If you are interested in a specific option, consult the
# [index](rdoc-ref:doc/irb/indexes.md@Index+of+Command-Line+Options).
#
# #### Command-Line Arguments
#
# Command-line arguments are passed to IRB in array `ARGV`:
#
#     $ irb --noscript Foo Bar Baz
#     irb(main):001> ARGV
#     => ["Foo", "Bar", "Baz"]
#     irb(main):002> exit
#     $
#
# Command-line option `--` causes everything that follows to be treated as
# arguments, even those that look like options:
#
#     $ irb --noscript -- --noscript -- Foo Bar Baz
#     irb(main):001> ARGV
#     => ["--noscript", "--", "Foo", "Bar", "Baz"]
#     irb(main):002> exit
#     $
#
# ### Configuration File
#
# You can initialize IRB via a *configuration file*.
#
# If command-line option `-f` is given, no configuration file is looked for.
#
# Otherwise, IRB reads and interprets a configuration file if one is available.
#
# The configuration file can contain any Ruby code, and can usefully include
# user code that:
#
# *   Can then be debugged in IRB.
# *   Configures IRB itself.
# *   Requires or loads files.
#
#
# The path to the configuration file is the first found among:
#
# *   The value of variable `$IRBRC`, if defined.
# *   The value of variable `$XDG_CONFIG_HOME/irb/irbrc`, if defined.
# *   File `$HOME/.irbrc`, if it exists.
# *   File `$HOME/.config/irb/irbrc`, if it exists.
# *   File `.irbrc` in the current directory, if it exists.
# *   File `irb.rc` in the current directory, if it exists.
# *   File `_irbrc` in the current directory, if it exists.
# *   File `$irbrc` in the current directory, if it exists.
#
#
# If the search fails, there is no configuration file.
#
# If the search succeeds, the configuration file is read as Ruby code, and so
# can contain any Ruby programming you like.
#
# Method `conf.rc?` returns `true` if a configuration file was read, `false`
# otherwise. Hash entry `IRB.conf[:RC]` also contains that value.
#
# ### Hash `IRB.conf`
#
# The initial entries in hash `IRB.conf` are determined by:
#
# *   Default values.
# *   Command-line options, which may override defaults.
# *   Direct assignments in the configuration file.
#
#
# You can see the hash by typing `IRB.conf`.
#
# Details of the entries' meanings are described in the relevant subsections
# below.
#
# If you are interested in a specific entry, consult the
# [index](rdoc-ref:doc/irb/indexes.md@Index+of+IRB.conf+Entries).
#
# ### Notes on Initialization Precedence
#
# *   Any conflict between an entry in hash `IRB.conf` and a command-line option
#     is resolved in favor of the hash entry.
# *   Hash `IRB.conf` affects the context only once, when the configuration file
#     is interpreted; any subsequent changes to it do not affect the context and
#     are therefore essentially meaningless.
#
#
# ### Initialization Script
#
# By default, the first command-line argument (after any options) is the path to
# a Ruby initialization script.
#
# IRB reads the initialization script and puts its content onto the IRB shell,
# just as if it were user-typed commands.
#
# Command-line option `--noscript` causes the first command-line argument to be
# treated as an ordinary argument (instead of an initialization script);
# `--script` is the default.
#
# ## Input
#
# This section describes the features that allow you to change the way IRB input
# works; see also [Input and Output](rdoc-ref:IRB@Input+and+Output).
#
# ### Input Command History
#
# By default, IRB stores a history of up to 1000 input commands in a file named
# `.irb_history`. The history file will be in the same directory as the
# [configuration file](rdoc-ref:IRB@Configuration+File) if one is found, or in
# `~/` otherwise.
#
# A new IRB session creates the history file if it does not exist, and appends
# to the file if it does exist.
#
# You can change the filepath by adding to your configuration file:
# `IRB.conf[:HISTORY_FILE] = *filepath*`, where *filepath* is a string filepath.
#
# During the session, method `conf.history_file` returns the filepath, and
# method `conf.history_file = *new_filepath*` copies the history to the file at
# *new_filepath*, which becomes the history file for the session.
#
# You can change the number of commands saved by adding to your configuration
# file: `IRB.conf[:SAVE_HISTORY] = *n*`, wheHISTORY_FILEre *n* is one of:
#
# *   Positive integer: the number of commands to be saved,
# *   Zero: all commands are to be saved.
# *   `nil`: no commands are to be saved,.
#
#
# During the session, you can use methods `conf.save_history` or
# `conf.save_history=` to retrieve or change the count.
#
# ### Command Aliases
#
# By default, IRB defines several command aliases:
#
#     irb(main):001> conf.command_aliases
#     => {:"$"=>:show_source, :"@"=>:whereami}
#
# You can change the initial aliases in the configuration file with:
#
#     IRB.conf[:COMMAND_ALIASES] = {foo: :show_source, bar: :whereami}
#
# You can replace the current aliases at any time with configuration method
# `conf.command_aliases=`; Because `conf.command_aliases` is a hash, you can
# modify it.
#
# ### End-of-File
#
# By default, `IRB.conf[:IGNORE_EOF]` is `false`, which means that typing the
# end-of-file character `Ctrl-D` causes the session to exit.
#
# You can reverse that behavior by adding `IRB.conf[:IGNORE_EOF] = true` to the
# configuration file.
#
# During the session, method `conf.ignore_eof?` returns the setting, and method
# `conf.ignore_eof = *boolean*` sets it.
#
# ### SIGINT
#
# By default, `IRB.conf[:IGNORE_SIGINT]` is `true`, which means that typing the
# interrupt character `Ctrl-C` causes the session to exit.
#
# You can reverse that behavior by adding `IRB.conf[:IGNORE_SIGING] = false` to
# the configuration file.
#
# During the session, method `conf.ignore_siging?` returns the setting, and
# method `conf.ignore_sigint = *boolean*` sets it.
#
# ### Automatic Completion
#
# By default, IRB enables [automatic
# completion](https://en.wikipedia.org/wiki/Autocomplete#In_command-line_interpr
# eters):
#
# You can disable it by either of these:
#
# *   Adding `IRB.conf[:USE_AUTOCOMPLETE] = false` to the configuration file.
# *   Giving command-line option `--noautocomplete` (`--autocomplete` is the
#     default).
#
#
# Method `conf.use_autocomplete?` returns `true` if automatic completion is
# enabled, `false` otherwise.
#
# The setting may not be changed during the session.
#
# ### Automatic Indentation
#
# By default, IRB automatically indents lines of code to show structure (e.g.,
# it indent the contents of a block).
#
# The current setting is returned by the configuration method
# `conf.auto_indent_mode`.
#
# The default initial setting is `true`:
#
#     irb(main):001> conf.auto_indent_mode
#     => true
#     irb(main):002* Dir.entries('.').select do |entry|
#     irb(main):003*   entry.start_with?('R')
#     irb(main):004> end
#     => ["README.md", "Rakefile"]
#
# You can change the initial setting in the configuration file with:
#
#     IRB.conf[:AUTO_INDENT] = false
#
# Note that the *current* setting *may not* be changed in the IRB session.
#
# ### Input Method
#
# The IRB input method determines how command input is to be read; by default,
# the input method for a session is IRB::RelineInputMethod. Unless the
# value of the TERM environment variable is 'dumb', in which case the
# most simplistic input method is used.
#
# You can set the input method by:
#
# *   Adding to the configuration file:
#
#     *   `IRB.conf[:USE_SINGLELINE] = true` or `IRB.conf[:USE_MULTILINE]=
#         false` sets the input method to IRB::ReadlineInputMethod.
#     *   `IRB.conf[:USE_SINGLELINE] = false` or `IRB.conf[:USE_MULTILINE] =
#         true` sets the input method to IRB::RelineInputMethod.
#
#
# *   Giving command-line options:
#
#     *   `--singleline` or `--nomultiline` sets the input method to
#         IRB::ReadlineInputMethod.
#     *   `--nosingleline` or `--multiline` sets the input method to
#         IRB::RelineInputMethod.
#     *   `--nosingleline` together with `--nomultiline` sets the
#         input to IRB::StdioInputMethod.
#
#
# Method `conf.use_multiline?` and its synonym `conf.use_reline` return:
#
# *   `true` if option `--multiline` was given.
# *   `false` if option `--nomultiline` was given.
# *   `nil` if neither was given.
#
#
# Method `conf.use_singleline?` and its synonym `conf.use_readline` return:
#
# *   `true` if option `--singleline` was given.
# *   `false` if option `--nosingleline` was given.
# *   `nil` if neither was given.
#
#
# ## Output
#
# This section describes the features that allow you to change the way IRB
# output works; see also [Input and Output](rdoc-ref:IRB@Input+and+Output).
#
# ### Return-Value Printing (Echoing)
#
# By default, IRB prints (echoes) the values returned by all input commands.
#
# You can change the initial behavior and suppress all echoing by:
#
# *   Adding to the configuration file: `IRB.conf[:ECHO] = false`. (The default
#     value for this entry is `nil`, which means the same as `true`.)
# *   Giving command-line option `--noecho`. (The default is `--echo`.)
#
#
# During the session, you can change the current setting with configuration
# method `conf.echo=` (set to `true` or `false`).
#
# As stated above, by default IRB prints the values returned by all input
# commands; but IRB offers special treatment for values returned by assignment
# statements, which may be:
#
# *   Printed with truncation (to fit on a single line of output), which is the
#     default; an ellipsis (`...` is suffixed, to indicate the truncation):
#
#         irb(main):001> x = 'abc' * 100
#
#
# > "abcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabc...
#
# *   Printed in full (regardless of the length).
# *   Suppressed (not printed at all)
#
#
# You can change the initial behavior by:
#
# *   Adding to the configuration file: `IRB.conf[:ECHO_ON_ASSIGNMENT] = false`.
#     (The default value for this entry is `niL`, which means the same as
#     `:truncate`.)
# *   Giving command-line option `--noecho-on-assignment` or
#     `--echo-on-assignment`. (The default is `--truncate-echo-on-assignment`.)
#
#
# During the session, you can change the current setting with configuration
# method `conf.echo_on_assignment=` (set to `true`, `false`, or `:truncate`).
#
# By default, IRB formats returned values by calling method `inspect`.
#
# You can change the initial behavior by:
#
# *   Adding to the configuration file: `IRB.conf[:INSPECT_MODE] = false`. (The
#     default value for this entry is `true`.)
# *   Giving command-line option `--noinspect`. (The default is `--inspect`.)
#
#
# During the session, you can change the setting using method
# `conf.inspect_mode=`.
#
# ### Multiline Output
#
# By default, IRB prefixes a newline to a multiline response.
#
# You can change the initial default value by adding to the configuration file:
#
#     IRB.conf[:NEWLINE_BEFORE_MULTILINE_OUTPUT] = false
#
# During a session, you can retrieve or set the value using methods
# `conf.newline_before_multiline_output?` and
# `conf.newline_before_multiline_output=`.
#
# Examples:
#
#     irb(main):001> conf.inspect_mode = false
#     => false
#     irb(main):002> "foo\nbar"
#     =>
#     foo
#     bar
#     irb(main):003> conf.newline_before_multiline_output = false
#     => false
#     irb(main):004> "foo\nbar"
#     => foo
#     bar
#
# ### Evaluation History
#
# By default, IRB saves no history of evaluations (returned values), and the
# related methods `conf.eval_history`, `_`, and `__` are undefined.
#
# You can turn on that history, and set the maximum number of evaluations to be
# stored:
#
# *   In the configuration file: add `IRB.conf[:EVAL_HISTORY] = *n*`. (Examples
#     below assume that we've added `IRB.conf[:EVAL_HISTORY] = 5`.)
# *   In the session (at any time): `conf.eval_history = *n*`.
#
#
# If `n` is zero, all evaluation history is stored.
#
# Doing either of the above:
#
# *   Sets the maximum size of the evaluation history; defines method
#     `conf.eval_history`, which returns the maximum size `n` of the evaluation
#     history:
#
#         irb(main):001> conf.eval_history = 5
#         => 5
#         irb(main):002> conf.eval_history
#         => 5
#
# *   Defines variable `_`, which contains the most recent evaluation, or `nil`
#     if none; same as method `conf.last_value`:
#
#         irb(main):003> _
#         => 5
#         irb(main):004> :foo
#         => :foo
#         irb(main):005> :bar
#         => :bar
#         irb(main):006> _
#         => :bar
#         irb(main):007> _
#         => :bar
#
# *   Defines variable `__`:
#
#     *   `__` unadorned: contains all evaluation history:
#
#             irb(main):008> :foo
#             => :foo
#             irb(main):009> :bar
#             => :bar
#             irb(main):010> :baz
#             => :baz
#             irb(main):011> :bat
#             => :bat
#             irb(main):012> :bam
#             => :bam
#             irb(main):013> __
#             =>
#             9 :bar
#             10 :baz
#             11 :bat
#             12 :bam
#             irb(main):014> __
#             =>
#             10 :baz
#             11 :bat
#             12 :bam
#             13 ...self-history...
#
#         Note that when the evaluation is multiline, it is displayed
#         differently.
#
#     *   `__[`*m*`]`:
#
#         *   Positive *m*:  contains the evaluation for the given line number,
#             or `nil` if that line number is not in the evaluation history:
#
#                 irb(main):015> __[12]
#                 => :bam
#                 irb(main):016> __[1]
#                 => nil
#
#         *   Negative *m*: contains the `mth`-from-end evaluation, or `nil` if
#             that evaluation is not in the evaluation history:
#
#                 irb(main):017> __[-3]
#                 => :bam
#                 irb(main):018> __[-13]
#                 => nil
#
#         *   Zero *m*: contains `nil`:
#
#                 irb(main):019> __[0]
#                 => nil
#
#
#
#
# ### Prompt and Return Formats
#
# By default, IRB uses the prompt and return value formats defined in its
# `:DEFAULT` prompt mode.
#
# #### The Default Prompt and Return Format
#
# The default prompt and return values look like this:
#
#     irb(main):001> 1 + 1
#     => 2
#     irb(main):002> 2 + 2
#     => 4
#
# The prompt includes:
#
# *   The name of the running program (`irb`); see [IRB
#     Name](rdoc-ref:IRB@IRB+Name).
# *   The name of the current session (`main`); See [IRB
#     Sessions](rdoc-ref:IRB@IRB+Sessions).
# *   A 3-digit line number (1-based).
#
#
# The default prompt actually defines three formats:
#
# *   One for most situations (as above):
#
#         irb(main):003> Dir
#         => Dir
#
# *   One for when the typed command is a statement continuation (adds trailing
#     asterisk):
#
#         irb(main):004* Dir.
#
# *   One for when the typed command is a string continuation (adds trailing
#     single-quote):
#
#         irb(main):005' Dir.entries('.
#
#
# You can see the prompt change as you type the characters in the following:
#
#     irb(main):001* Dir.entries('.').select do |entry|
#     irb(main):002*   entry.start_with?('R')
#     irb(main):003> end
#     => ["README.md", "Rakefile"]
#
# #### Pre-Defined Prompts
#
# IRB has several pre-defined prompts, stored in hash `IRB.conf[:PROMPT]`:
#
#     irb(main):001> IRB.conf[:PROMPT].keys
#     => [:NULL, :DEFAULT, :CLASSIC, :SIMPLE, :INF_RUBY, :XMP]
#
# To see the full data for these, type `IRB.conf[:PROMPT]`.
#
# Most of these prompt definitions include specifiers that represent values like
# the IRB name, session name, and line number; see [Prompt
# Specifiers](rdoc-ref:IRB@Prompt+Specifiers).
#
# You can change the initial prompt and return format by:
#
# *   Adding to the configuration file: `IRB.conf[:PROMPT] = *mode*` where
#     *mode* is the symbol name of a prompt mode.
# *   Giving a command-line option:
#
#     *   `--prompt *mode*`: sets the prompt mode to *mode*. where *mode* is the
#         symbol name of a prompt mode.
#     *   `--simple-prompt` or `--sample-book-mode`: sets the prompt mode to
#         `:SIMPLE`.
#     *   `--inf-ruby-mode`: sets the prompt mode to `:INF_RUBY` and suppresses
#         both `--multiline` and `--singleline`.
#     *   `--noprompt`: suppresses prompting; does not affect echoing.
#
#
#
# You can retrieve or set the current prompt mode with methods
#
# `conf.prompt_mode` and `conf.prompt_mode=`.
#
# If you're interested in prompts and return formats other than the defaults,
# you might experiment by trying some of the others.
#
# #### Custom Prompts
#
# You can also define custom prompts and return formats, which may be done
# either in an IRB session or in the configuration file.
#
# A prompt in IRB actually defines three prompts, as seen above. For simple
# custom data, we'll make all three the same:
#
#     irb(main):001* IRB.conf[:PROMPT][:MY_PROMPT] = {
#     irb(main):002*   PROMPT_I: ': ',
#     irb(main):003*   PROMPT_C: ': ',
#     irb(main):004*   PROMPT_S: ': ',
#     irb(main):005*   RETURN: '=> '
#     irb(main):006> }
#     => {:PROMPT_I=>": ", :PROMPT_C=>": ", :PROMPT_S=>": ", :RETURN=>"=> "}
#
# If you define the custom prompt in the configuration file, you can also make
# it the current prompt by adding:
#
#     IRB.conf[:PROMPT_MODE] = :MY_PROMPT
#
# Regardless of where it's defined, you can make it the current prompt in a
# session:
#
#     conf.prompt_mode = :MY_PROMPT
#
# You can view or modify the current prompt data with various configuration
# methods:
#
# *   `conf.prompt_mode`, `conf.prompt_mode=`.
# *   `conf.prompt_c`, `conf.c=`.
# *   `conf.prompt_i`, `conf.i=`.
# *   `conf.prompt_s`, `conf.s=`.
# *   `conf.return_format`, `return_format=`.
#
#
# #### Prompt Specifiers
#
# A prompt's definition can include specifiers for which certain values are
# substituted:
#
# *   `%N`: the name of the running program.
# *   `%m`: the value of `self.to_s`.
# *   `%M`: the value of `self.inspect`.
# *   `%l`: an indication of the type of string; one of `"`, `'`, `/`, `]`.
# *   `%NNi`: Indentation level. NN is a 2-digit number that specifies the number
#             of digits of the indentation level (03 will result in 001).
# *   `%NNn`: Line number. NN is a 2-digit number that specifies the number
#             of digits of the line number (03 will result in 001).
# *   `%%`: Literal `%`.
#
#
# ### Verbosity
#
# By default, IRB verbosity is disabled, which means that output is smaller
# rather than larger.
#
# You can enable verbosity by:
#
# *   Adding to the configuration file: `IRB.conf[:VERBOSE] = true` (the default
#     is `nil`).
# *   Giving command-line options `--verbose` (the default is `--noverbose`).
#
#
# During a session, you can retrieve or set verbosity with methods
# `conf.verbose` and `conf.verbose=`.
#
# ### Help
#
# Command-line option `--version` causes IRB to print its help text and exit.
#
# ### Version
#
# Command-line option `--version` causes IRB to print its version text and exit.
#
# ## Input and Output
#
# ### Color Highlighting
#
# By default, IRB color highlighting is enabled, and is used for both:
#
# *   Input: As you type, IRB reads the typed characters and highlights elements
#     that it recognizes; it also highlights errors such as mismatched
#     parentheses.
# *   Output: IRB highlights syntactical elements.
#
#
# You can disable color highlighting by:
#
# *   Adding to the configuration file: `IRB.conf[:USE_COLORIZE] = false` (the
#     default value is `true`).
# *   Giving command-line option `--nocolorize`
#
#
# ## Debugging
#
# Command-line option `-d` sets variables `$VERBOSE` and `$DEBUG` to `true`;
# these have no effect on IRB output.
#
# ### Warnings
#
# Command-line option `-w` suppresses warnings.
#
# Command-line option `-W[*level*]` sets warning level;
#
# * 0=silence
# * 1=medium
# * 2=verbose
#
# ## Other Features
#
# ### Load Modules
#
# You can specify the names of modules that are to be required at startup.
#
# Array `conf.load_modules` determines the modules (if any) that are to be
# required during session startup. The array is used only during session
# startup, so the initial value is the only one that counts.
#
# The default initial value is `[]` (load no modules):
#
#     irb(main):001> conf.load_modules
#     => []
#
# You can set the default initial value via:
#
# *   Command-line option `-r`
#
#          $ irb -r csv -r json
#         irb(main):001> conf.load_modules
#         => ["csv", "json"]
#
# *   Hash entry `IRB.conf[:LOAD_MODULES] = *array*`:
#
#         IRB.conf[:LOAD_MODULES] = %w[csv, json]
#
#
# Note that the configuration file entry overrides the command-line options.
#
# ### RI Documentation Directories
#
# You can specify the paths to RI documentation directories that are to be
# loaded (in addition to the default directories) at startup; see details about
# RI by typing `ri --help`.
#
# Array `conf.extra_doc_dirs` determines the directories (if any) that are to be
# loaded during session startup. The array is used only during session startup,
# so the initial value is the only one that counts.
#
# The default initial value is `[]` (load no extra documentation):
#
#     irb(main):001> conf.extra_doc_dirs
#     => []
#
# You can set the default initial value via:
#
# *   Command-line option `--extra_doc_dir`
#
#         $ irb --extra-doc-dir your_doc_dir --extra-doc-dir my_doc_dir
#         irb(main):001> conf.extra_doc_dirs
#         => ["your_doc_dir", "my_doc_dir"]
#
# *   Hash entry `IRB.conf[:EXTRA_DOC_DIRS] = *array*`:
#
#         IRB.conf[:EXTRA_DOC_DIRS] = %w[your_doc_dir my_doc_dir]
#
#
# Note that the configuration file entry overrides the command-line options.
#
# ### IRB Name
#
# You can specify a name for IRB.
#
# The default initial value is `'irb'`:
#
#     irb(main):001> conf.irb_name
#     => "irb"
#
# You can set the default initial value via hash entry `IRB.conf[:IRB_NAME] =
# *string*`:
#
#     IRB.conf[:IRB_NAME] = 'foo'
#
# ### Application Name
#
# You can specify an application name for the IRB session.
#
# The default initial value is `'irb'`:
#
#     irb(main):001> conf.ap_name
#     => "irb"
#
# You can set the default initial value via hash entry `IRB.conf[:AP_NAME] =
# *string*`:
#
#     IRB.conf[:AP_NAME] = 'my_ap_name'
#
# ### Configuration Monitor
#
# You can monitor changes to the configuration by assigning a proc to
# `IRB.conf[:IRB_RC]` in the configuration file:
#
#     IRB.conf[:IRB_RC] = proc {|conf| puts conf.class }
#
# Each time the configuration is changed, that proc is called with argument
# `conf`:
#
# ### Encodings
#
# Command-line option `-E *ex*[:*in*]` sets initial external (ex) and internal
# (in) encodings.
#
# Command-line option `-U` sets both to UTF-8.
#
# ### Commands
#
# Please use the `help` command to see the list of available commands.
#
# ### IRB Sessions
#
# IRB has a special feature, that allows you to manage many sessions at once.
#
# You can create new sessions with Irb.irb, and get a list of current sessions
# with the `jobs` command in the prompt.
#
# #### Configuration
#
# The command line options, or IRB.conf, specify the default behavior of
# Irb.irb.
#
# On the other hand, each conf in IRB@Command-Line+Options is used to
# individually configure IRB.irb.
#
# If a proc is set for `IRB.conf[:IRB_RC]`, its will be invoked after execution
# of that proc with the context of the current session as its argument. Each
# session can be configured using this mechanism.
#
# #### Session variables
#
# There are a few variables in every Irb session that can come in handy:
#
# `_`
# :   The value command executed, as a local variable
# `__`
# :   The history of evaluated commands. Available only if
#     `IRB.conf[:EVAL_HISTORY]` is not `nil` (which is the default). See also
#     IRB::Context#eval_history= and IRB::History.
# `__[line_no]`
# :   Returns the evaluation value at the given line number, `line_no`. If
#     `line_no` is a negative, the return value `line_no` many lines before the
#     most recent return value.
#
#
# ## Restrictions
#
# Ruby code typed into IRB behaves the same as Ruby code in a file, except that:
#
# *   Because IRB evaluates input immediately after it is syntactically
#     complete, some results may be slightly different.
# *   Forking may not be well behaved.
#
module IRB

  # An exception raised by IRB.irb_abort
  class Abort < Exception;end

  class << self
    # The current IRB::Context of the session, see IRB.conf
    #
    #     irb
    #     irb(main):001:0> IRB.CurrentContext.irb_name = "foo"
    #     foo(main):002:0> IRB.conf[:MAIN_CONTEXT].irb_name #=> "foo"
    def CurrentContext # :nodoc:
      conf[:MAIN_CONTEXT]
    end

    # Initializes IRB and creates a new Irb.irb object at the `TOPLEVEL_BINDING`
    def start(ap_path = nil)
      STDOUT.sync = true
      $0 = File::basename(ap_path, ".rb") if ap_path

      setup(ap_path)

      if @CONF[:SCRIPT]
        irb = Irb.new(nil, @CONF[:SCRIPT])
      else
        irb = Irb.new
      end
      irb.run(@CONF)
    end

    # Quits irb
    def irb_exit(*) # :nodoc:
      throw :IRB_EXIT, false
    end

    # Aborts then interrupts irb.
    #
    # Will raise an Abort exception, or the given `exception`.
    def irb_abort(irb, exception = Abort) # :nodoc:
      irb.context.thread.raise exception, "abort then interrupt!"
    end
  end

  class Irb
    # Note: instance and index assignment expressions could also be written like:
    # "foo.bar=(1)" and "foo.[]=(1, bar)", when expressed that way, the former be
    # parsed as :assign and echo will be suppressed, but the latter is parsed as a
    # :method_add_arg and the output won't be suppressed

    PROMPT_MAIN_TRUNCATE_LENGTH = 32
    PROMPT_MAIN_TRUNCATE_OMISSION = '...'
    CONTROL_CHARACTERS_PATTERN = "\x00-\x1F"

    # Returns the current context of this irb session
    attr_reader :context
    # The lexer used by this irb session
    attr_accessor :scanner

    attr_reader :from_binding

    # Creates a new irb session
    def initialize(workspace = nil, input_method = nil, from_binding: false)
      @from_binding = from_binding
      @context = Context.new(self, workspace, input_method)
      @context.workspace.load_helper_methods_to_main
      @signal_status = :IN_IRB
      @scanner = RubyLex.new
      @line_no = 1
    end

    # A hook point for `debug` command's breakpoint after :IRB_EXIT as well as its
    # clean-up
    def debug_break
      # it means the debug integration has been activated
      if defined?(DEBUGGER__) && DEBUGGER__.respond_to?(:capture_frames_without_irb)
        # after leaving this initial breakpoint, revert the capture_frames patch
        DEBUGGER__.singleton_class.send(:alias_method, :capture_frames, :capture_frames_without_irb)
        # and remove the redundant method
        DEBUGGER__.singleton_class.send(:undef_method, :capture_frames_without_irb)
      end
    end

    def debug_readline(binding)
      workspace = IRB::WorkSpace.new(binding)
      context.replace_workspace(workspace)
      context.workspace.load_helper_methods_to_main
      @line_no += 1

      # When users run:
      # 1.  Debugging commands, like `step 2`
      # 2.  Any input that's not irb-command, like `foo = 123`
      #
      #
      # Irb#eval_input will simply return the input, and we need to pass it to the
      # debugger.
      input = nil
      forced_exit = catch(:IRB_EXIT) do
        if IRB.conf[:SAVE_HISTORY] && context.io.support_history_saving?
          # Previous IRB session's history has been saved when `Irb#run` is exited We need
          # to make sure the saved history is not saved again by resetting the counter
          context.io.reset_history_counter

          begin
            input = eval_input
          ensure
            context.io.save_history
          end
        else
          input = eval_input
        end
        false
      end

      Kernel.exit if forced_exit

      if input&.include?("\n")
        @line_no += input.count("\n") - 1
      end

      input
    end

    def run(conf = IRB.conf)
      in_nested_session = !!conf[:MAIN_CONTEXT]
      conf[:IRB_RC].call(context) if conf[:IRB_RC]
      prev_context = conf[:MAIN_CONTEXT]
      conf[:MAIN_CONTEXT] = context

      save_history = !in_nested_session && conf[:SAVE_HISTORY] && context.io.support_history_saving?

      if save_history
        context.io.load_history
      end

      prev_trap = trap("SIGINT") do
        signal_handle
      end

      begin
        if defined?(RubyVM.keep_script_lines)
          keep_script_lines_backup = RubyVM.keep_script_lines
          RubyVM.keep_script_lines = true
        end

        forced_exit = catch(:IRB_EXIT) do
          eval_input
        end
      ensure
        # Do not restore to nil. It will cause IRB crash when used with threads.
        IRB.conf[:MAIN_CONTEXT] = prev_context if prev_context

        RubyVM.keep_script_lines = keep_script_lines_backup if defined?(RubyVM.keep_script_lines)
        trap("SIGINT", prev_trap)
        conf[:AT_EXIT].each{|hook| hook.call}

        context.io.save_history if save_history
        Kernel.exit if forced_exit
      end
    end

    # Evaluates input for this session.
    def eval_input
      configure_io

      each_top_level_statement do |statement, line_no|
        signal_status(:IN_EVAL) do
          begin
            # If the integration with debugger is activated, we return certain input if it
            # should be dealt with by debugger
            if @context.with_debugger && statement.should_be_handled_by_debugger?
              return statement.code
            end

            @context.evaluate(statement, line_no)

            if @context.echo? && !statement.suppresses_echo?
              if statement.is_assignment?
                if @context.echo_on_assignment?
                  output_value(@context.echo_on_assignment? == :truncate)
                end
              else
                output_value
              end
            end
          rescue SystemExit, SignalException
            raise
          rescue Interrupt, Exception => exc
            handle_exception(exc)
            @context.workspace.local_variable_set(:_, exc)
          end
        end
      end
    end

    def read_input(prompt)
      signal_status(:IN_INPUT) do
        @context.io.prompt = prompt
        if l = @context.io.gets
          print l if @context.verbose?
        else
          if @context.ignore_eof? and @context.io.readable_after_eof?
            l = "\n"
            if @context.verbose?
              printf "Use \"exit\" to leave %s\n", @context.ap_name
            end
          else
            print "\n" if @context.prompting?
          end
        end
        l
      end
    end

    def readmultiline
      prompt = generate_prompt([], false, 0)

      # multiline
      return read_input(prompt) if @context.io.respond_to?(:check_termination)

      # nomultiline
      code = +''
      line_offset = 0
      loop do
        line = read_input(prompt)
        unless line
          return code.empty? ? nil : code
        end

        code << line
        return code if command?(code)

        tokens, opens, terminated = @scanner.check_code_state(code, local_variables: @context.local_variables)
        return code if terminated

        line_offset += 1
        continue = @scanner.should_continue?(tokens)
        prompt = generate_prompt(opens, continue, line_offset)
      end
    end

    def each_top_level_statement
      loop do
        code = readmultiline
        break unless code
        yield build_statement(code), @line_no
        @line_no += code.count("\n")
      rescue RubyLex::TerminateLineInput
      end
    end

    def build_statement(code)
      if code.match?(/\A\n*\z/)
        return Statement::EmptyInput.new
      end

      code.force_encoding(@context.io.encoding)
      if (command, arg = parse_command(code))
        command_class = Command.load_command(command)
        Statement::Command.new(code, command_class, arg)
      else
        is_assignment_expression = @scanner.assignment_expression?(code, local_variables: @context.local_variables)
        Statement::Expression.new(code, is_assignment_expression)
      end
    end

    ASSIGN_OPERATORS_REGEXP = Regexp.union(%w[= += -= *= /= %= **= &= |= &&= ||= ^= <<= >>=])

    def parse_command(code)
      command_name, arg = code.strip.split(/\s+/, 2)
      return unless code.lines.size == 1 && command_name

      arg ||= ''
      command = command_name.to_sym
      # Command aliases are always command. example: $, @
      if (alias_name = @context.command_aliases[command])
        return [alias_name, arg]
      end

      # Assignment-like expression is not a command
      return if arg.start_with?(ASSIGN_OPERATORS_REGEXP) && !arg.start_with?(/==|=~/)

      # Local variable have precedence over command
      return if @context.local_variables.include?(command)

      # Check visibility
      public_method = !!Kernel.instance_method(:public_method).bind_call(@context.main, command) rescue false
      private_method = !public_method && !!Kernel.instance_method(:method).bind_call(@context.main, command) rescue false
      if Command.execute_as_command?(command, public_method: public_method, private_method: private_method)
        [command, arg]
      end
    end

    def command?(code)
      !!parse_command(code)
    end

    def configure_io
      if @context.io.respond_to?(:check_termination)
        @context.io.check_termination do |code|
          if Reline::IOGate.in_pasting?
            rest = @scanner.check_termination_in_prev_line(code, local_variables: @context.local_variables)
            if rest
              Reline.delete_text
              rest.bytes.reverse_each do |c|
                Reline.ungetc(c)
              end
              true
            else
              false
            end
          else
            next true if command?(code)

            _tokens, _opens, terminated = @scanner.check_code_state(code, local_variables: @context.local_variables)
            terminated
          end
        end
      end
      if @context.io.respond_to?(:dynamic_prompt)
        @context.io.dynamic_prompt do |lines|
          tokens = RubyLex.ripper_lex_without_warning(lines.map{ |l| l + "\n" }.join, local_variables: @context.local_variables)
          line_results = IRB::NestingParser.parse_by_line(tokens)
          tokens_until_line = []
          line_results.map.with_index do |(line_tokens, _prev_opens, next_opens, _min_depth), line_num_offset|
            line_tokens.each do |token, _s|
              # Avoid appending duplicated token. Tokens that include "n" like multiline
              # tstring_content can exist in multiple lines.
              tokens_until_line << token if token != tokens_until_line.last
            end
            continue = @scanner.should_continue?(tokens_until_line)
            generate_prompt(next_opens, continue, line_num_offset)
          end
        end
      end

      if @context.io.respond_to?(:auto_indent) and @context.auto_indent_mode
        @context.io.auto_indent do |lines, line_index, byte_pointer, is_newline|
          next nil if lines == [nil] # Workaround for exit IRB with CTRL+d
          next nil if !is_newline && lines[line_index]&.byteslice(0, byte_pointer)&.match?(/\A\s*\z/)

          code = lines[0..line_index].map { |l| "#{l}\n" }.join
          tokens = RubyLex.ripper_lex_without_warning(code, local_variables: @context.local_variables)
          @scanner.process_indent_level(tokens, lines, line_index, is_newline)
        end
      end
    end

    def convert_invalid_byte_sequence(str, enc)
      str.force_encoding(enc)
      str.scrub { |c|
        c.bytes.map{ |b| "\\x#{b.to_s(16).upcase}" }.join
      }
    end

    def encode_with_invalid_byte_sequence(str, enc)
      conv = Encoding::Converter.new(str.encoding, enc)
      dst = String.new
      begin
        ret = conv.primitive_convert(str, dst)
        case ret
        when :invalid_byte_sequence
          conv.insert_output(conv.primitive_errinfo[3].dump[1..-2])
          redo
        when :undefined_conversion
          c = conv.primitive_errinfo[3].dup.force_encoding(conv.primitive_errinfo[1])
          conv.insert_output(c.dump[1..-2])
          redo
        when :incomplete_input
          conv.insert_output(conv.primitive_errinfo[3].dump[1..-2])
        when :finished
        end
        break
      end while nil
      dst
    end

    def handle_exception(exc)
      if exc.backtrace[0] =~ /\/irb(2)?(\/.*|-.*|\.rb)?:/ && exc.class.to_s !~ /^IRB/ &&
         !(SyntaxError === exc) && !(EncodingError === exc)
        # The backtrace of invalid encoding hash (ex. {"\xAE": 1}) raises EncodingError without lineno.
        irb_bug = true
      else
        irb_bug = false
        # To support backtrace filtering while utilizing Exception#full_message, we need to clone
        # the exception to avoid modifying the original exception's backtrace.
        exc = exc.clone
        filtered_backtrace = exc.backtrace.map { |l| @context.workspace.filter_backtrace(l) }.compact
        backtrace_filter = IRB.conf[:BACKTRACE_FILTER]

        if backtrace_filter
          if backtrace_filter.respond_to?(:call)
            filtered_backtrace = backtrace_filter.call(filtered_backtrace)
          else
            warn "IRB.conf[:BACKTRACE_FILTER] #{backtrace_filter} should respond to `call` method"
          end
        end

        exc.set_backtrace(filtered_backtrace)
      end

      highlight = Color.colorable?

      order =
        if RUBY_VERSION < '3.0.0'
          STDOUT.tty? ? :bottom : :top
        else # '3.0.0' <= RUBY_VERSION
          :top
        end

      message = exc.full_message(order: order, highlight: highlight)
      message = convert_invalid_byte_sequence(message, exc.message.encoding)
      message = encode_with_invalid_byte_sequence(message, IRB.conf[:LC_MESSAGES].encoding) unless message.encoding.to_s.casecmp?(IRB.conf[:LC_MESSAGES].encoding.to_s)
      message = message.gsub(/((?:^\t.+$\n)+)/) { |m|
        case order
        when :top
          lines = m.split("\n")
        when :bottom
          lines = m.split("\n").reverse
        end
        unless irb_bug
          if lines.size > @context.back_trace_limit
            omit = lines.size - @context.back_trace_limit
            lines = lines[0..(@context.back_trace_limit - 1)]
            lines << "\t... %d levels..." % omit
          end
        end
        lines = lines.reverse if order == :bottom
        lines.map{ |l| l + "\n" }.join
      }
      # The "<top (required)>" in "(irb)" may be the top level of IRB so imitate the main object.
      message = message.gsub(/\(irb\):(?<num>\d+):in (?<open_quote>[`'])<(?<frame>top \(required\))>'/) { "(irb):#{$~[:num]}:in #{$~[:open_quote]}<main>'" }
      puts message
      puts 'Maybe IRB bug!' if irb_bug
    rescue Exception => handler_exc
      begin
        puts exc.inspect
        puts "backtraces are hidden because #{handler_exc} was raised when processing them"
      rescue Exception
        puts 'Uninspectable exception occurred'
      end
    end

    # Evaluates the given block using the given `path` as the Context#irb_path and
    # `name` as the Context#irb_name.
    #
    # Used by the irb command `source`, see IRB@IRB+Sessions for more information.
    def suspend_name(path = nil, name = nil)
      @context.irb_path, back_path = path, @context.irb_path if path
      @context.irb_name, back_name = name, @context.irb_name if name
      begin
        yield back_path, back_name
      ensure
        @context.irb_path = back_path if path
        @context.irb_name = back_name if name
      end
    end

    # Evaluates the given block using the given `workspace` as the
    # Context#workspace.
    #
    # Used by the irb command `irb_load`, see IRB@IRB+Sessions for more information.
    def suspend_workspace(workspace)
      current_workspace = @context.workspace
      @context.replace_workspace(workspace)
      yield
    ensure
      @context.replace_workspace current_workspace
    end

    # Evaluates the given block using the given `input_method` as the Context#io.
    #
    # Used by the irb commands `source` and `irb_load`, see IRB@IRB+Sessions for
    # more information.
    def suspend_input_method(input_method)
      back_io = @context.io
      @context.instance_eval{@io = input_method}
      begin
        yield back_io
      ensure
        @context.instance_eval{@io = back_io}
      end
    end

    # Handler for the signal SIGINT, see Kernel#trap for more information.
    def signal_handle
      unless @context.ignore_sigint?
        print "\nabort!\n" if @context.verbose?
        exit
      end

      case @signal_status
      when :IN_INPUT
        print "^C\n"
        raise RubyLex::TerminateLineInput
      when :IN_EVAL
        IRB.irb_abort(self)
      when :IN_LOAD
        IRB.irb_abort(self, LoadAbort)
      when :IN_IRB
        # ignore
      else
        # ignore other cases as well
      end
    end

    # Evaluates the given block using the given `status`.
    def signal_status(status)
      return yield if @signal_status == :IN_LOAD

      signal_status_back = @signal_status
      @signal_status = status
      begin
        yield
      ensure
        @signal_status = signal_status_back
      end
    end

    def output_value(omit = false) # :nodoc:
      str = @context.inspect_last_value
      multiline_p = str.include?("\n")
      if omit
        winwidth = @context.io.winsize.last
        if multiline_p
          first_line = str.split("\n").first
          result = @context.newline_before_multiline_output? ? (@context.return_format % first_line) : first_line
          output_width = Reline::Unicode.calculate_width(result, true)
          diff_size = output_width - Reline::Unicode.calculate_width(first_line, true)
          if diff_size.positive? and output_width > winwidth
            lines, _ = Reline::Unicode.split_by_width(first_line, winwidth - diff_size - 3)
            str = "%s..." % lines.first
            str += "\e[0m" if Color.colorable?
            multiline_p = false
          else
            str = str.gsub(/(\A.*?\n).*/m, "\\1...")
            str += "\e[0m" if Color.colorable?
          end
        else
          output_width = Reline::Unicode.calculate_width(@context.return_format % str, true)
          diff_size = output_width - Reline::Unicode.calculate_width(str, true)
          if diff_size.positive? and output_width > winwidth
            lines, _ = Reline::Unicode.split_by_width(str, winwidth - diff_size - 3)
            str = "%s..." % lines.first
            str += "\e[0m" if Color.colorable?
          end
        end
      end

      if multiline_p && @context.newline_before_multiline_output?
        str = "\n" + str
      end

      Pager.page_content(format(@context.return_format, str), retain_content: true)
    end

    # Outputs the local variables to this current session, including #signal_status
    # and #context, using IRB::Locale.
    def inspect
      ary = []
      for iv in instance_variables
        case (iv = iv.to_s)
        when "@signal_status"
          ary.push format("%s=:%s", iv, @signal_status.id2name)
        when "@context"
          ary.push format("%s=%s", iv, eval(iv).__to_s__)
        else
          ary.push format("%s=%s", iv, eval(iv))
        end
      end
      format("#<%s: %s>", self.class, ary.join(", "))
    end

    private

    def generate_prompt(opens, continue, line_offset)
      ltype = @scanner.ltype_from_open_tokens(opens)
      indent = @scanner.calc_indent_level(opens)
      continue = opens.any? || continue
      line_no = @line_no + line_offset

      if ltype
        f = @context.prompt_s
      elsif continue
        f = @context.prompt_c
      else
        f = @context.prompt_i
      end
      f = "" unless f
      if @context.prompting?
        p = format_prompt(f, ltype, indent, line_no)
      else
        p = ""
      end
      if @context.auto_indent_mode and !@context.io.respond_to?(:auto_indent)
        unless ltype
          prompt_i = @context.prompt_i.nil? ? "" : @context.prompt_i
          ind = format_prompt(prompt_i, ltype, indent, line_no)[/.*\z/].size +
            indent * 2 - p.size
          p += " " * ind if ind > 0
        end
      end
      p
    end

    def truncate_prompt_main(str) # :nodoc:
      str = str.tr(CONTROL_CHARACTERS_PATTERN, ' ')
      if str.size <= PROMPT_MAIN_TRUNCATE_LENGTH
        str
      else
        str[0, PROMPT_MAIN_TRUNCATE_LENGTH - PROMPT_MAIN_TRUNCATE_OMISSION.size] + PROMPT_MAIN_TRUNCATE_OMISSION
      end
    end

    def format_prompt(format, ltype, indent, line_no) # :nodoc:
      format.gsub(/%([0-9]+)?([a-zA-Z%])/) do
        case $2
        when "N"
          @context.irb_name
        when "m"
          main_str = @context.main.to_s rescue "!#{$!.class}"
          truncate_prompt_main(main_str)
        when "M"
          main_str = @context.main.inspect rescue "!#{$!.class}"
          truncate_prompt_main(main_str)
        when "l"
          ltype
        when "i"
          if indent < 0
            if $1
              "-".rjust($1.to_i)
            else
              "-"
            end
          else
            if $1
              format("%" + $1 + "d", indent)
            else
              indent.to_s
            end
          end
        when "n"
          if $1
            format("%" + $1 + "d", line_no)
          else
            line_no.to_s
          end
        when "%"
          "%" unless $1
        end
      end
    end
  end
end

class Binding
  # Opens an IRB session where `binding.irb` is called which allows for
  # interactive debugging. You can call any methods or variables available in the
  # current scope, and mutate state if you need to.
  #
  # Given a Ruby file called `potato.rb` containing the following code:
  #
  #     class Potato
  #       def initialize
  #         @cooked = false
  #         binding.irb
  #         puts "Cooked potato: #{@cooked}"
  #       end
  #     end
  #
  #     Potato.new
  #
  # Running `ruby potato.rb` will open an IRB session where `binding.irb` is
  # called, and you will see the following:
  #
  #     $ ruby potato.rb
  #
  #     From: potato.rb @ line 4 :
  #
  #         1: class Potato
  #         2:   def initialize
  #         3:     @cooked = false
  #      => 4:     binding.irb
  #         5:     puts "Cooked potato: #{@cooked}"
  #         6:   end
  #         7: end
  #         8:
  #         9: Potato.new
  #
  #     irb(#<Potato:0x00007feea1916670>):001:0>
  #
  # You can type any valid Ruby code and it will be evaluated in the current
  # context. This allows you to debug without having to run your code repeatedly:
  #
  #     irb(#<Potato:0x00007feea1916670>):001:0> @cooked
  #     => false
  #     irb(#<Potato:0x00007feea1916670>):002:0> self.class
  #     => Potato
  #     irb(#<Potato:0x00007feea1916670>):003:0> caller.first
  #     => ".../2.5.1/lib/ruby/2.5.0/irb/workspace.rb:85:in `eval'"
  #     irb(#<Potato:0x00007feea1916670>):004:0> @cooked = true
  #     => true
  #
  # You can exit the IRB session with the `exit` command. Note that exiting will
  # resume execution where `binding.irb` had paused it, as you can see from the
  # output printed to standard output in this example:
  #
  #     irb(#<Potato:0x00007feea1916670>):005:0> exit
  #     Cooked potato: true
  #
  # See IRB for more information.
  def irb(show_code: true)
    # Setup IRB with the current file's path and no command line arguments
    IRB.setup(source_location[0], argv: []) unless IRB.initialized?
    # Create a new workspace using the current binding
    workspace = IRB::WorkSpace.new(self)
    # Print the code around the binding if show_code is true
    STDOUT.print(workspace.code_around_binding) if show_code
    # Get the original IRB instance
    debugger_irb = IRB.instance_variable_get(:@debugger_irb)

    irb_path = File.expand_path(source_location[0])

    if debugger_irb
      # If we're already in a debugger session, set the workspace and irb_path for the original IRB instance
      debugger_irb.context.replace_workspace(workspace)
      debugger_irb.context.irb_path = irb_path
      # If we've started a debugger session and hit another binding.irb, we don't want
      # to start an IRB session instead, we want to resume the irb:rdbg session.
      IRB::Debug.setup(debugger_irb)
      IRB::Debug.insert_debug_break
      debugger_irb.debug_break
    else
      # If we're not in a debugger session, create a new IRB instance with the current
      # workspace
      binding_irb = IRB::Irb.new(workspace, from_binding: true)
      binding_irb.context.irb_path = irb_path
      binding_irb.run(IRB.conf)
      binding_irb.debug_break
    end
  end
end
